antkeeper
/
superbuild


								#define TINYEXR_IMPLEMENTATION

								#include "tinyexr.h"


								#ifdef __clang__

								#pragma clang diagnostic push

								#pragma clang diagnostic ignored "-Weverything"

								#endif


								#define STB_IMAGE_RESIZE_IMPLEMENTATION

								#include "stb_image_resize.h"


								#define STB_IMAGE_WRITE_IMPLEMENTATION

								#include "stb_image_write.h"


								#include "cxxopts.hpp"


								#ifdef __clang__

								#pragma clang diagnostic pop

								#endif


								namespace {


								static void vnormalize(float v[3]) {

								  const float d2 = v[0] * v[0] + v[1] * v[1] + v[2] * v[2];

								  if (d2 > 1.0e-6f) {

								    const float inv_d = 1.0f / std::sqrt(d2);

								    v[0] *= inv_d;

								    v[1] *= inv_d;

								    v[2] *= inv_d;

								  }

								  return;

								}


								template<typename T>

								static inline T clamp(const T v, const T min_v, const T max_v)

								{

								  return std::max(min_v, std::min(max_v, v));

								}


								//

								// Compute gradient from scalar field.

								// dx = (x + 1, y    ) - (x, y)

								// dy = (x    , y + 1) - (x, y)

								//

								// TODO(syoyo): Use central difference with texel filtering.

								//

								static void Gradient(

								  const std::vector<float> &src,

								  const size_t width,

								  const size_t height,

								  const size_t x, const size_t y,

								  const float bumpness,

								  float dir[3])

								{

								  const size_t x1 = clamp(x + 1, size_t(0), width - 1);

								  const size_t y1 = clamp(y + 1, size_t(0), height - 1);


								  float v00 = src[y * width + x];

								  float v01 = src[y * width + x1];

								  float v11 = src[y1 * width + x];


								  float dx = bumpness * (v01 - v00);

								  float dy = bumpness * (v11 - v00);


								  dir[0] = dx;

								  dir[1] = dy;

								  dir[2] = 0.0f;


								}


								///

								/// Convert image(bump map for single channel, vector displacement map for 3 channels input) to normal map.

								/// @param[in] base Base value fo

								///

								///

								static void ToNormalMap(

								  const std::vector<float> &src,

								  const size_t width,

								  const size_t height,

								  const size_t channels,

								  const float strength,

								  std::vector<float> *dst)

								{

								  assert((channels == 1) || (channels == 3) || (channels == 4));


								  dst->resize(width * height * 3);


								  if (channels == 1) {

								    // bump map

								    for (size_t y = 0; y < height; y++) {

								      for (size_t x = 0; x < width; x++) {

								        float d[3];

								        Gradient(src, width, height, x, y, strength, d);


								        (*dst)[3 * (y * width + x) + 0] = d[0];

								        (*dst)[3 * (y * width + x) + 1] = d[1];

								        (*dst)[3 * (y * width + x) + 2] = d[2];


								      }

								    }


								  } else {

								    // vector displacement map


								    for (size_t y = 0; y < height; y++) {

								      for (size_t x = 0; x < width; x++) {


								        float v[3];

								        v[0] = src[channels * (y * width + x) + 0];

								        v[1] = src[channels * (y * width + x) + 1];

								        v[2] = src[channels * (y * width + x) + 2];


								        v[0] *= strength;

								        v[1] *= strength;

								        v[2] *= strength;


								        // Add (0, 0, 1)

								        v[2] += 1.0f;


								        // TODO(syoyo): Add option to not normalize.

								        vnormalize(v);


								        (*dst)[3 * (y * width + x) + 0] = 0.5f * v[0] + 0.5f;

								        (*dst)[3 * (y * width + x) + 1] = 0.5f * v[1] + 0.5f;

								        (*dst)[3 * (y * width + x) + 2] = 0.5f * v[2] + 0.5f;


								      }

								    }


								  }


								}


								inline unsigned char ftouc(float f)

								{

								  int i = static_cast<int>(f * 255.0f);

								  if (i > 255) i = 255;

								  if (i < 0) i = 0;


								  return static_cast<unsigned char>(i);

								}


								bool SaveImage(const char* filename, const float* rgb, int width, int height) {


								  std::vector<unsigned char> dst(width * height * 3);


								  for (size_t i = 0; i < width * height; i++) {

								      dst[i * 3 + 0] = ftouc(rgb[i * 3 + 0]);

								      dst[i * 3 + 1] = ftouc(rgb[i * 3 + 1]);

								      dst[i * 3 + 2] = ftouc(rgb[i * 3 + 2]);

								  }


								  int ret = stbi_write_png(filename, width, height, 3, static_cast<const void*>(dst.data()), width * 3);


								  return (ret > 0);

								}


								std::string GetFileExtension(const std::string &filename) {

								  if (filename.find_last_of(".") != std::string::npos)

								    return filename.substr(filename.find_last_of(".") + 1);

								  return "";

								}


								} // namespace


								int main(int argc, char **argv)

								{

								  cxxopts::Options options("normalmap", "help");

								  options.add_options()

								    ("s,strength", "Strength(scaling) for normal value", cxxopts::value<float>())

								    ("i,input", "Input filename", cxxopts::value<std::string>())

								    ("o,output", "Output filename", cxxopts::value<std::string>())

								    ("r,resize", "Resize image. 0.5 = 50%%, 0.1 = 10%%", cxxopts::value<float>())

								    ;


								  auto result = options.parse(argc, argv);


								  if (result.count("input") == 0) {

								    std::cerr << "input filename missing" << std::endl;

								    return EXIT_FAILURE;

								  }


								  if (result.count("output") == 0) {

								    std::cerr << "output filename missing" << std::endl;

								    return EXIT_FAILURE;

								  }


								  float strength = 1.0f;

								  if (result.count("strength")) {

								    strength = result["strength"].as<float>();

								  }


								  float resize = 1.0f;

								  if (result.count("resize")) {

								    resize = result["resize"].as<float>();

								  }


								  std::string input_filename = result["input"].as<std::string>();

								  std::string output_filename = result["output"].as<std::string>();


								  std::vector<float> src;

								  size_t src_width;

								  size_t src_height;


								  {

								    float *rgba = nullptr;

								    int width, height;

								    const char *err = nullptr;

								    int ret = LoadEXR(&rgba, &width, &height, input_filename.c_str(), &err);

								    if (TINYEXR_SUCCESS != ret) {

								      std::cerr << "Failed to load EXR file [" << input_filename << "] code = " << ret << std::endl;

								      if (err) {

								        std::cerr << err << std::endl;

								        FreeEXRErrorMessage(err);

								      }


								      return EXIT_FAILURE;

								    }


								    std::cout << "loaded EXR. width x height = " << width << "x" << height << std::endl;

								    src.resize(size_t(width * height * 3));


								    // ignore alpha for now

								    for (size_t i = 0; i < size_t(width * height); i++) {

								      src[3 * i + 0] = rgba[4 * i + 0];

								      src[3 * i + 1] = rgba[4 * i + 1];

								      src[3 * i + 2] = rgba[4 * i + 2];

								    }


								    src_width  = size_t(width);

								    src_height = size_t(height);


								    free(rgba);

								  }


								  std::cout << "strength = " << strength << std::endl;


								  std::vector<float> dst;

								  ToNormalMap(src, src_width, src_height, 3, strength, &dst);


								  std::string ext = GetFileExtension(output_filename);

								  if ((ext.compare("png") == 0) ||

								      (ext.compare("PNG") == 0)) {

								    // Save as LDR image.

								    // Do not apply sRGB conversion for PNG(LDR) image.

								    if (!SaveImage(output_filename.c_str(), dst.data(), int(src_width), int(src_height))) {

								      std::cerr << "Failed to write a file : " << output_filename << std::endl;

								      return EXIT_FAILURE;

								    }

								  } else {

								    // assume EXR.

								    float *rgba = nullptr;

								    int width, height;

								    int ret = SaveEXR(dst.data(), int(src_width), int(src_height), /* component */3, /* fp16 */0, output_filename.c_str(), nullptr);

								    if (TINYEXR_SUCCESS != ret) {

								      std::cerr << "Failed to save EXR file [" << input_filename << "] code = " << ret << std::endl;

								      return EXIT_FAILURE;

								    }

								  }


								  return EXIT_SUCCESS;

								}